Switching-mode power supply (smps) having overvoltage cutoff function, and method of cutting off overvoltage and image forming apparatus using the smps

ABSTRACT

A switching-mode power supply (SMPS) for an image forming apparatus which may prevent an overvoltage supplied to the SMPS, and damage to circuits in the SMPS in the image forming apparatus. The SMPS includes a rectifying circuit to rectify an alternating-current (AC) voltage input from an external power supply source into a direct-current (DC) voltage, a transformer to transform the rectified DC voltage input to a primary coil and output the transformed DC voltage to a secondary coil, a main switch that is connected to the primary coil and switches an output of the transformer, a first overvoltage detecting unit to determine whether the rectified DC voltage is an overvoltage by comparing the rectified DC voltage with a first reference voltage, and a switching control unit to control a switching operation of the main switch based on a result of the determination.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of Korean Patent Application No.10-2011-0121730, filed on Nov. 21, 2011, in the Korean IntellectualProperty Office, the disclosure of which is incorporated herein in itsentirety by reference.

BACKGROUND

1. Field

The present general inventive concept relates to a switching-mode powersupply (SMPS) having an overvoltage cutoff function, and a method ofcutting off an overvoltage and an image forming apparatus using theSMPS, and more particularly, to an SMPS for an image forming apparatuswhich may minimize and/or prevent an overvoltage and damage to thecircuits in the SMPS and the image forming apparatus when a voltagehigher than a rated voltage of the SMPS is supplied to the SMPS. Thepresent general inventive concept also relates to a method of cuttingoff an overvoltage and an image forming apparatus and/or electronicdevice including the SMPS.

2. Description of the Related Art

A switching-mode power supply (SMPS) refers to a device that transformsan alternating-current (AC) voltage supplied from an external powersupply source by using a transformer and outputs a direct-current (DC)voltage appropriate for an electronic product. An SMPS is moreefficient, more durable, smaller, and lighter than a linear powersupply.

Since an image forming apparatus, such as a printer or a copier,requires a power supply having a simple structure, a small size, and astable power supply function, an SMPS is often used.

While South Korea uses an AC voltage of 220 V at 60 Hz as a standardvoltage, other countries use various standard voltages according totheir actual conditions. Although some countries use voltages of 100 V,127 V, and 140 V, many countries use a voltage of 110 V or 220 V. InSouth Korea, an AC voltage of 220 V at 60 Hz is supplied to eachhousehold, and thus, most electronic products, such as an image formingapparatus, are only for 220 V or for both 110 V and 220 V.

An image forming apparatus receives an AC voltage from the outside andtransforms the AC voltage into a DC voltage to be used therein. Suchtransformation occurs in an SMPS. Since parts in an SMPS vary accordingto an AC voltage input from the outside, if the AC voltage applied fromthe outside is higher than a rated voltage of the SMPS, the parts in theSMPS may be damaged, thereby leading to product liability (PL).

When an overvoltage is applied to an SMPS, a fuse of an AC power inputterminal has blown by using a low-voltage varistor in order to avoid PL.

SUMMARY

The present general inventive concept provides a switching-mode powersupply (SMPS) having an overvoltage cutoff function, a method of cuttingoff an overvoltage, and an image forming apparatus using the SMPS.Technical problems to be solved by embodiments of the present generalinventive concept are not limited to those described above, and othertechnical problems may be solved by from the following embodiments.

Additional features and utilities of the present general inventiveconcept will be set forth in part in the description which follows and,in part, will be obvious from the description, or may be learned bypractice of the general inventive concept.

In exemplary embodiments of the present general inventive concept, anSMPS is provided for an image forming apparatus, the SMPS including arectifying circuit unit to rectify an alternating-current (AC) voltageinput from an external power supply source into a direct-current (DC)voltage, a transformer to transform the rectified DC voltage input to aprimary coil and outputs the transformed DC voltage to a secondary coil,a main switch that is connected to the primary coil to switch an outputof the transformer, a first overvoltage detecting unit to determinewhether the rectified DC voltage is an overvoltage by comparing therectified DC voltage with a first reference voltage, and a switchingcontrol unit to control a switching operation of the main switch basedon a result of the determination.

The switching control unit may stop the switching operation when it isdetermined that the rectified DC voltage is an overvoltage.

The switching control unit may be a pulse width modulation (PMW)integrated circuit (IC) and may stop the switching operation when asignal indicating an overvoltage is input to a predetermined Pin of thePWM IC form the first overvoltage detecting unit.

The first overvoltage detecting unit may include a power detecting unitto detect the rectified DC voltage, and a first overvoltage determiningunit to determine whether the detected DC voltage is an overvoltage bycomparing the detected DC voltage with the first reference voltage.

The first overvoltage determining unit may determine whether thedetected DC voltage is an overvoltage by using a Zener diode that hasthe first reference voltage as a breakdown voltage.

The first overvoltage detecting unit may determine whether the rectifiedDC voltage is an overvoltage by determining whether the rectified DCvoltage is higher than the first reference voltage that corresponds to amaximum allowance of a rated voltage of the SMPS.

A second overvoltage detecting unit may transform the input AC voltageand determine whether the transformed AC voltage is an overvoltage bycomparing the transformed AC voltage with a second reference voltage,and a cutoff unit that may cut off the input AC voltage input to therectifying circuit based on a result of the determination of the secondovervoltage detecting unit.

The second overvoltage detecting unit may include a potentialtransformer to transform the input AC voltage according to apredetermined turns ratio, a rectifier to rectify the transformed ACvoltage into a DC voltage, and a second overvoltage determining unit todetermine whether the DC voltage rectified by the rectifier is anovervoltage by comparing the rectified DC voltage with the secondreference voltage.

The second overvoltage determining unit may determine whether therectified DC voltage is an overvoltage by using a Zener diode that hasthe second reference voltage as a breakdown voltage.

The cutoff unit may cut off the input AC voltage input to the rectifyingcircuit unit by using any one of a relay, a photo triac, and aphotocoupler.

Exemplary embodiments of the present general inventive concept, may alsoprovide a method of cutting off an overvoltage performed by aswitching-mode power supply (SMPS) for an image forming apparatus, themethod including detecting a direct-current (DC) voltage obtained byrectifying an alternating-current (AC) voltage input from an externalpower supply source, determining whether the detected DC voltage is anovervoltage by comparing the detected DC voltage with a first referencevoltage, and controlling a switching operation of a main switch thatswitches an output of a transformer to transform the rectified DCvoltage, based on a result of the determination.

The controlling of the switching operation of the main switch may alsoinclude stopping the switching operation when it is determined that thedetected DC voltage is an overvoltage.

The determination of whether the detected DC voltage is an overvoltagemay also include determining whether the detected DC voltage is anovervoltage by determining whether the detected DC voltage is higherthan the first reference voltage that corresponds to a maximum allowanceof a rated voltage of the SMPS.

The method of cutting off an overvoltage performed by the SMPS for theimage forming apparatus may further include transforming the input ACvoltage and determining whether the transformed AC voltage is anovervoltage by comparing the transformed AC voltage with a secondreference voltage, and cutting off the input AC voltage before the inputAC voltage is rectified, based on a result of the determination.

The determination of whether the transformed AC voltage is anovervoltage by comparing the transformed AC voltage with the secondreference voltage may include transforming the input AC voltageaccording to a predetermined turns ration by using a potentialtransformer, rectifying the transformed AC voltage into a DC voltage,and determining whether the rectified DC voltage is an overvoltage bycomparing the rectified DC voltage with the second reference voltage.

Exemplary embodiments of the present general inventive concept may alsoprovide an image forming apparatus including a switching-mode powersupply (SMPS), wherein the SMPS includes a rectifying circuit unit torectify an alternating-current (AC) voltage input from an external powersupply source into a direct-current (DC) voltage, a transformer totransform the rectified DC voltage input to a primary coil and outputsthe transformed DC voltage to a secondary coil, a main switch that isconnected to the primary coil and switches an output of the transformer,a first overvoltage detecting unit to determine whether the rectified DCvoltage is an overvoltage by comparing the rectified DC voltage with afirst reference voltage, and a switching control unit to control aswitching operation of the main switch based on a result of thedetermination.

The SMPS may also include a second overvoltage detecting unit totransform the input AC voltage and to determine whether the transformedAC voltage is an overvoltage by comparing the transformed AC voltagewith a second reference voltage, and a cutoff unit to cut off the inputAC voltage input to the rectifying circuit based on a result of thedetermination of the second overvoltage detecting unit.

Exemplary embodiments of the present general inventive concept may alsoprovide a switching-mode power supply (SMPS) including a rectifying unitto rectify a voltage input from a supply source, a first overvoltagedetecting unit to detect the voltage rectified by the rectifying unitand to determine if the voltage is within a predetermined voltage rangeallowed by the SMPS, and a switching control unit to stop a switchingoperation of a main switch that is connected to the switching controlunit to prevent an output unit from outputting the voltage when thedetected voltage is greater than the predetermined voltage range.

The switching control may control the switching operation of the mainswitch to prevent the output unit from generating an output voltagegreater than the predetermined voltage range.

The first overvoltage detecting unit may include an overvoltagedetermining unit to allow the first overvoltage detecting unit todetermine if the voltage input from the supply source is greater thanthe predetermined voltage range.

The first overvoltage detecting unit may include a Zener diode to allowthe first overvoltage detecting unit to determine if the voltage inputform the supply source is greater than the predetermined voltage range.

The switching-mode power supply may also include a second overvoltagedetecting unit to detect the voltage input from the supply source and todetermine if the voltage is greater than the predetermined voltagerange, and a cutoff unit to prevent the voltage input from the supplysource from entering a filter unit when the voltage is greater than thepredetermined voltage range.

The second overvoltage detecting unit may also include a Zener to allowthe second overvoltage detecting unit to determine if the voltage inputfrom the supply source is greater than the predetermined voltage range.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and/or other features and utilities of the present generalinventive concept will become more apparent by describing in detailexemplary embodiments thereof with reference to the attached drawings inwhich:

FIG. 1 is a block diagram illustrating an image forming apparatusincluding a switching-mode power supply (SMPS), according to anembodiment of the present general inventive concept;

FIG. 1A is block diagram illustrating an image forming apparatusincluding a switching-mode power supply (SMPS) and a fax unit and/or ascanning unit, according to an embodiment of the present generalinventive concept;

FIG. 2 is a block diagram illustrating an SMPS for an image formingapparatus having an overvoltage cutoff function, according to anembodiment of the present general inventive concept;

FIG. 2A is a block diagram illustrating an SMPS for an image formingapparatus having an overvoltage cutoff function, according to anembodiment of the present general inventive concept;

FIG. 3 is a circuit diagram illustrating an SMPS for an image formingapparatus having an overvoltage cutoff function, according to anembodiment of the present general inventive concept;

FIG. 4 is a flowchart illustrating a method of cutting off anovervoltage which is performed by the SMPS of FIG. 2, according to anembodiment of the present general inventive concept;

FIG. 5 is a circuit diagram illustrating an SMPS for an image formingapparatus having an overvoltage cutoff function, according to anotherembodiment of the present general inventive concept;

FIG. 6 is a block diagram illustrating an SMPS for an image formingapparatus having an overvoltage cutoff function, according to anotherembodiment of the present general inventive concept;

FIG. 7 is a circuit diagram illustrating an SMPS for an image formingapparatus having an overvoltage cutoff function, according to anotherembodiment of the present general inventive concept; and

FIG. 8 is a flowchart illustrating a method of cutting off anovervoltage performed by the SMPS of FIG. 6, according to anotherembodiment of the present general inventive concept.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present general inventive concept will now be described more fullywith reference to the accompanying drawings, in which exemplaryembodiments of the present general inventive concept are illustrated.The present general inventive concept may, however, be embodied in manydifferent forms and should not be construed as being limited to theembodiments set forth herein; rather these embodiments are provided sothat this disclosure will be thorough and complete, and will fullyconvey the concept of the present general inventive concept to one ofordinary skill in the art. Numerous modifications and adaptations willbe readily apparent to one of ordinary skill in this art from thedetailed description and the embodiments without departing from thespirit and scope of the present general inventive concept.

Reference will now be made in detail to the embodiments of the presentgeneral inventive concept, examples of which are illustrated in theaccompanying drawings, wherein like reference numerals refer to the likeelements throughout. The embodiments are described below in order toexplain the present general inventive concept while referring to thefigures.

The embodiments relate to a switching-mode power supply (SMPS), and moreparticularly, to an SMPS for an image forming apparatus. Examples of amethod of converting energy in circuits include a non-isolation method,such as a buck method, a boost method, or a buck-boost method, and anisolation method, such as a flyback method, a forward method, or apush-pull method. Although an SMPS using a flyback method is exemplarilyexplained, the present general inventive concept is not limited thereto.A detailed explanation of elements or features well known to one ofordinary skill in the art is not provided.

FIGS. 1-1A are block diagrams illustrating an image forming apparatus100 including an SMPS, according to an embodiment of the present generalinventive concept. Referring to FIG. 1, the image forming apparatus 100includes a main system 110, a communication interface unit 120, a userinterface unit 130, a storage unit 140, an image forming unit 150, and apower supply 160. In this case, the power supply 160 may be the SMPS. Itwould be understood by one of ordinary skill in the art that the imageforming apparatus 100 may further include general-purpose elements otherthan the elements illustrated in FIGS. 1 and 1A.

For example, as illustrated in FIG. 1A, the image forming apparatus 100may include a main system 110, a communication interface unit 120, auser interface unit 130, a storage unit 140, a power supply 160, a faxunit 102, or a scanning unit 104.

The fax unit 102 may generate fax data from at least one documentreceived from an external source 103 (e.g. a laptop or desktop computer,mobile phone, etc.), and the generated fax data may be transmitted viathe communication interface unit 120. The storage unit 140 can alsoinclude document data that can be converted by the fax unit 102 to faxdata to be transmitted via the communication interface unit 120. Thescanning unit 104 may be a scanner to scan at least one documentinputted by the external source 103 to generate scan data to be storedin the storage unit 140, transmitted via the communication interfaceunit 120, or printed via the image forming unit 150 of the image formingapparatus 100.

Referring to FIGS. 1 and 1A, the main system 110 controls an overallfunction of the image forming apparatus 100. The main system 110 mayinclude a controller to control an overall function of the image formingapparatus 100. The main system 110 may operate at a first output voltageoutput from the power supply 160. The first output voltage may be, butis not limited to, a direct-current (DC) voltage of 3.3 V or 5 V.

The communication interface unit 120 may include a modem to transmit orto receive a fax message, a network module to connect to a network, anda universal serial bus (USB) host module to form a channel through whichdata is exchanged with a removable storage medium, according to thefunction of the image forming apparatus 100. In this case, examples ofan external device that is connectable to the image forming apparatus100 via a wired or wireless network may include a facsimile machine, acomputer system, a mobile terminal, a personal digital assistant (PDA),and a server.

The user interface unit 130 obtains an input signal from the externalsource 103. For example, the user interface unit 130 may includeinput/output devices such as a display panel, a mouse, a keyboard, atouch screen, a monitor, and a speaker provided on the image formingapparatus 100.

The storage unit 140 stores print data, scan data, and data generatedwhen the image forming apparatus 100 operates.

The image forming unit 150 forms an image and prints print data onpaper. The image forming unit 150 includes hardware units to performelectrifying, exposing, developing, transferring, and fixing operations,and software modules to drive the hardware units. The image forming unit150 may operate at a second output voltage output from the power supply160. The second output voltage may be, but is not limited to, a DCvoltage of 12 V or 24 V.

Since the power supply 160 performs the same operation as that of anSMPS described below, a description made with reference to FIGS. 2through 8 may apply to the power supply 160 of FIG. 1.

FIG. 2 is a block diagram illustrating an SMPS 200 for an image formingapparatus having an overvoltage cutoff function, according to anembodiment of the present general inventive concept. The SMPS 200 may beincluded in any of various image forming apparatuses, such as a printer,a copier, and a multifunction product. Referring to FIG. 2, the SMPS 200includes an alternating-current (AC) power input unit 210, a filter unit220, a rectifying circuit unit 230, a smoothing circuit unit 240, atransforming unit 250, a switching unit 260, an output unit 270, and anovervoltage detecting unit 280. The switching unit 260 may include amain switch 262 and a switching control unit 264. It would be understoodby one of ordinary skill in the art that the SMPS 200 may furtherinclude elements other than the elements shown in FIG. 2.

FIG. 2A is a block diagram illustrating an SMPS for an image formingapparatus having an overvoltage cutoff function as in FIG. 2. The SMPS200 of FIG. 2A may include an alternating-current (AC) power input unit210, a filter unit 220, a rectifying circuit unit 230, a smoothingcircuit unit 240, a transforming unit 250, a switching unit 260, anoutput unit 270, an overvoltage detecting unit 280, a main switch 262,and a switching control unit 264 as in FIG. 2. The SMPS 200 of FIG. 2Amay include a photocoupler 272 having a light-emitting diode to receivethe output voltage of the output unit 270 and to emit light according tothe output voltage. The photocoupler 272 may include a phototransistorto receive light emitted by the light-emitting diode and convert thelight into electrical energy. The photocoupler 272 allows the switchingcontrol unit 264 to monitor an output voltage and determine if theoutput voltage is within a predetermined operational voltage range ofthe image forming apparatus by comparing the output voltage with thepredetermined operational voltage range of the image forming apparatus.

Referring to FIG. 2, the AC power input unit 210 receives an AC voltage,a magnitude and direction of which periodically vary according time,from an external power supply source. For example, since South Koreauses an AC voltage of 220 V at 60 Hz as a standard voltage, the ACvoltage input to the SMPS from the external power supply source may bean AC voltage of 220 V at 60 Hz.

The filter unit 220 can remove electrical noise. The filter unit 220 canremove electrical noise input from the AC power input unit 110, orminimize and/or prevent electrical noise generated in the SMPS 200 fromexiting. The filter unit 220 may include an inductor called acommon-mode choke, and a capacitor that is an X-capacitor or aY-capacitor. For example, the filter unit 120 may be an electromagneticinterference (EMI) filter. The filter unit 120 filters noise, such asEMI generated due to an AC voltage. The EMI refers to a phenomenon wherean electromagnetic wave generated from an electronic product affects theoperation of the electronic product or other devices.

The rectifying circuit unit 230 rectifies an AC voltage. For example,the rectifying circuit unit 230 may be a bridge diode rectifyingcircuit, in other words, a bridge rectifier. The bridge diode rectifyingcircuit may be an arrangement of four diodes in a bridge circuitconfiguration. The feature of the bridge diode rectifying circuit isthat the polarity of the output is the same regardless of the polarityat the input.

The smoothing circuit unit 240 smoothes rectified power. That is, an ACvoltage is rectified by the rectifying circuit unit 230 into a pulsatingvoltage, not a DC voltage. The smoothing circuit unit 240 reduces aripple of the pulsating voltage. The smoothing circuit unit 240 mayinclude a capacitor and a resistor. The capacitor can reduce the rippleof rectified power, and the resistor discharges electric chargesaccumulated in the capacitor in order to minimize and/or prevent productliability (PL). The smoothing circuit unit 240 may include only acapacitor without a resistor. A magnitude of a DC voltage output fromthe smoothing circuit unit 240 varies according to an AC voltage inputfrom the outside. If an AC voltage input from the outside is 110 V, a DCvoltage of about 155 V is output, and if an AC voltage input from theoutside is 220 V, a DC voltage of about 310 V is output. A DC voltageoutput from the smoothing circuit unit 240 is input to the transformingunit 250 and the overvoltage detecting unit 280.

The transforming unit 250 may include at least one transformer. Aprimary coil and a secondary coil of the transformer may have apredetermined turns ratio therebetween, and the transforming unit 250may increase or decrease power input to the transformer through thesmoothing circuit unit 240 to a predetermined DC voltage according tothe turns ratio. For example, the image forming apparatus uses a DCvoltage of 3.3 V, 5 V, 12 V, or 24 V. Since a voltage input to theprimary coil of the transformer through the smoothing circuit unit 240is a DC voltage of about 155 V or 310 V, the transforming unit 250 maydecrease power to a voltage appropriate for the image forming apparatusby adjusting the turns ratio.

In order to transfer energy from the primary coil to the secondary coilof the transformer, a current may be varied. Since a DC voltage passingthrough the smoothing circuit unit 240 can be input to the primary coilof the transformer included in the SMPS 200, as described above, adevice may be used to cause variations in a current. Current variationsmay be performed by the switching unit 260. For example, the switchingunit 260 may generate square wave power by being turned on or off inorder to cause variations in a DC voltage input to the primary coil ofthe transformer.

The switching unit 260 includes the main switch 262 and the switchingcontrol unit 264 to control the main switch 262. The main switch 262 isrepeatedly turned on or off at a predetermined frequency of tens of KHz.When the main switch 262 is turned on, energy is accumulated on aprimary side of the transformer, and when the main switch 262 is turnedoff, the energy accumulated on the primary side is transferred to asecondary side. As a period of time for which the main switch 262 isturned on increases, energy is accumulated and transferred to thesecondary side. The switching control unit 264 controls a period of timefor which the main switch 262 is turned on or off. The switching controlunit 264 may be a pulse-width modulation (PWM) integrated circuit (IC).

Referring to FIG. 2A, the switching control unit 264 monitors an outputvoltage by using a photocoupler 272 and compares the output voltage witha voltage appropriate for an electronic product. When the output voltageis higher than the voltage appropriate for the electronic product, anon-time is reduced, when the output voltage is equal to the voltageappropriate for the electronic product, the on-time is maintained, andwhen the output voltage is lower than the appropriate voltage, theon-time is increased to maintain the output voltage.

Referring to FIGS. 2 and 2A, the output unit 270, which is a circuitconnected to the secondary coil of the transformer, outputs a completeDC voltage by removing a ripple of a voltage transformed by thetransformer. The output unit 270 may include a rectifying circuit. Anoutput voltage passing through the output unit 270 may be a DC voltageof 3.3 V, 5 V, 12 V, or 24 V, and may be a voltage appropriate for anelectronic product.

The overvoltage detecting unit 280 detects a DC voltage output from thesmoothing circuit unit 240, and determines whether the detected DCvoltage is an overvoltage by comparing the detected DC voltage with areference voltage. For example, a maximum allowance of a rated voltageof the SMPS 200 may be set as the reference voltage, and whether a DCvoltage output from the smoothing circuit unit 240 is an overvoltage maybe determined by determining whether the DC voltage is higher than thereference voltage.

The reference voltage may be set variously. For example, if the SMPS 200uses an AC voltage of 110 V as a rated voltage, a DC voltage passingthrough the smoothing circuit unit 240 may be a 155 V. If an error of15% is allowed, the DC voltage passing through the smoothing circuitunit 240 may be determined to be a rated voltage when the DC voltageranges from about 132 V to 178 V. However, when the DC voltage passingthrough the smoothing circuit unit 240 exceeds 178 V, which is a maximumallowance of the rated voltage, the DC voltage may be determined to bean overvoltage. As such, whether a DC voltage is an overvoltage may bedetermined by using a maximum allowance of a rated voltage of the SMPS200 as the reference voltage. Alternatively, if an AC voltage of 220 Vis applied to the SMPS 200 that uses an AC voltage of 110 V as a ratedvoltage, a DC voltage passing through the smoothing circuit unit 240 maybe 310 V. In this case, if an error of 15% is allowed, the DC voltagepassing through the smoothing circuit unit 240 may range from about 264V to 357 V. Accordingly, when the DC voltage passing through thesmoothing circuit unit 240 is equal to or higher than 264 V, it may bedetermined that an overvoltage of 220 V is applied to the SMPS 200. Ifboth voltages of 110 V and 220 V are used as supply power as in SouthKorea, whether an overvoltage of 220 V is applied to the SMPS 200 may bedetermined in the same manner. That is, whether a DC voltage is anovervoltage may be determined by using a minimum allowance of 220 V as areference voltage.

If it is determined that a DC voltage output from the smoothing circuitunit 240 is an overvoltage, the overvoltage detecting unit 280 outputs asignal indicating that an overvoltage is applied to the switchingcontrol unit 264.

In a normal operation mode in which a rated voltage is applied to theSMPS 200, the switching control unit 264 switches the main switch 262 bycontrolling an operation of the main switch 262, and in an abnormaloperation mode in which an overvoltage is applied to the SMPS 200, theswitching control unit 264 prevents energy from being transferred fromthe primary coil to the secondary coil of the transformer by stopping aswitching operation of the main switch 262. The switching control unit264 may be a PWM IC or a switching control circuit. FIG. 3 shows theformer case and FIG. 5 shows the latter case.

FIG. 3 is a circuit diagram illustrating an SMPS 300 for an imageforming apparatus, according to an embodiment of the present generalinventive concept. Referring to FIG. 3, the SMPS 300 includes an ACpower input unit 310, a filter unit 320, a rectifying circuit unit 330,a smoothing circuit unit 340, a transforming unit 350, a main switch362, a switching control unit 364, an output unit 370, and anovervoltage detecting unit 380. The description of the SMPS 200 madewith reference to FIG. 2 may apply to the SMPS 300 of FIG. 3. As shownin FIG. 3, the switching control unit 364 may be a PWM IC. It would beunderstood by one of ordinary skill in the art that the SMPS 300 mayfurther include elements other than the elements shown in FIG. 3.

An AC voltage is applied to the AC power input unit 310 from an externalpower supply source, and is output to the filter unit 320. A fuse F maybe disposed between the AC power input unit 310 and the filter unit 320.The filter unit 320 may be an EMI filter, as illustrated in FIG. 3. AnAC voltage from which noise is removed by the filter unit 320 is inputto the rectifying circuit unit 330 and is rectified. The rectified poweris changed to a DC voltage with a reduced ripple by passing through thesmoothing circuit unit 340 including a capacitor C1. The transformingunit 350 may be a transformer including a primary coil and a secondarycoil which are isolated from each other, as illustrated in FIG. 3. TheDC voltage passing through the smoothing circuit unit 340 is input tothe primary coil of the transformer, and variations occur in the DCvoltage input to the primary coil due to a switching operation of themain switch 362. The main switch 362 may be a transistor, as illustratedin FIG. 3, but the present embodiment is not limited thereto and may beany of various switching devices, such as a metal-oxide semiconductorfield-effect transistor (MOSFET). Energy is accumulated and transferredby the transformer according to the switching operation of the mainswitch 362. A voltage transformed by the transformer is transferred tothe secondary coil, and a more stable DC voltage can be output with adiode D2 and a capacitor C3 of a circuit included in the output unit370. The output unit 370 may include a half-wave rectifying circuit asshown in FIG. 3, but the present embodiment is not limited thereto andthe output unit 370 may include any of various rectifying circuits, suchas a full-wave rectifying circuit.

The switching operation of the main switch 362 may be adjusted by aswitching control signal output from the switching control unit 364, andthe switching control unit 364 may be the PWM IC, as illustrated in FIG.3. Power to drive the switching control unit 364 may be supplied byfeeding back a voltage output from the output unit 370. In this case,the output unit 370 and the switching control unit 364 may be connectedto each other through a photocoupler 372. Similar to FIG. 2A, thephotocoupler 372 in FIG. 3 may include a light-emitting diode and aphototransistor. The light-emitting diode acts as an emitter, and thephototransistor acts as a receiver of the photocoupler 372. Thelight-emitting diode may be disposed close to an output of the outputunit 370 to receive the output voltage of the output unit 370 and emitlight according to the output voltage, and the phototransistor may bedisposed close to the switching control unit 364 to receive lightemitted by the light-emitting diode and convert the light intoelectrical energy. When the phototransistor receives light and allowsthe light to pass therethrough, power is supplied to a power inputterminal of the switching control unit 364 through a circuit including aresistor R2 and a capacitor C2.

The switching control unit 364 may include an overvoltage protection(OVP) pin in order to protect the circuit. A signal indicating that theovervoltage detecting unit 380 determines that an abnormal voltage or anovervoltage is applied can be input to the OVP pin. A protection circuitconnected to the OVP pin may be disposed in the switching control unit364. For example, when a signal indicating that an overvoltage isapplied is input to the OVP pin, the protection circuit may cut off aswitching control signal output from the switching control unit 364 tothe main switch 362.

The overvoltage detecting unit 380 may be configured such that a diodeD1, a Zener diode ZD, and a resistor R1 are connected in series asillustrated in FIG. 3. The overvoltage detecting unit 380 may include apower detecting unit to detect power input to the primary coil of thetransformer and an overvoltage determining unit to determine whether thedetected power is an overvoltage by comparing the detected power with areference voltage. In FIG. 3, the diode D1 connected to the smoothingcircuit unit 340 may be the power detecting unit, and the Zener diode ZDand the resistor R1 connected to the Zener diode ZD may be theovervoltage determining unit. Power output from the smoothing circuitunit 340 can be transferred through the diode D1 to the Zener diode ZDthat is reversely connected to the diode D1. The Zener diode ZD may havea preset breakdown voltage (in other words, a Zener voltage). In thiscase, the preset breakdown voltage may become a reference voltage todetermine the existence of an overvoltage. When a voltage higher thanthe preset breakdown voltage of the Zener diode ZD reversely connectedto the diode D1 is input to the Zener diode ZD, the voltage passesthrough the Zener diode ZD, and when a voltage lower than the breakdownvoltage is input to the Zener diode ZD, the voltage does not passthrough the Zener diode ZD. If a reference voltage to determine theexistence of an overvoltage is the breakdown voltage of the Zener diodeZD, it may be determined whether a DC voltage output from the smoothingcircuit unit 340 is an overvoltage by determining whether the DC voltagepasses through the Zener diode ZD. When a DC voltage output from thesmoothing circuit unit 340 is an overvoltage, the DC voltage passesthrough the Zener diode ZD, a signal is transmitted to the OVP pin ofthe switching control unit 364 through the resistor R1, and theswitching control unit 364 cuts off a switching control signal outputfrom the switching control unit 364 in order to stop a switchingoperation of the main switch 362. As a result, an output voltage is notgenerated in the output unit 370 connected to the secondary side of thetransformer, thereby preventing an overvoltage from affecting a loadterminal.

FIG. 4 is a flowchart illustrating a method of cutting off anovervoltage performed by the SMPS 200 of FIG. 2, according to anembodiment of the present general inventive concept.

Referring to FIG. 4, in operation 410, the overvoltage detecting unit280 detects a DC voltage output through the rectifying circuit unit 230and the smoothing circuit unit 240. The DC voltage is the same as a DCvoltage input to the primary coil of the transformer of the transformingunit 250.

In operation 420, the overvoltage detecting unit 280 determines whetherthe detected DC voltage is an overvoltage by comparing the detected DCvoltage with a reference voltage. When the detected DC voltage is lowerthan the reference voltage, the SMPS 200 normally operates. When thedetected DC voltage is higher than the reference voltage, an overvoltagehas been applied, and the method proceeds to operation 430.

In operation 430, when a signal indicating that an overvoltage isapplied is input from the overvoltage detecting unit 280, the switchingcontrol unit 264 stops a switching operation of the main switch 262.Accordingly, an output voltage is not generated in the output unit 270connected to the secondary side of the transformer.

FIG. 5 is a circuit diagram illustrating an SMPS for an image formingapparatus having an overvoltage cutoff function, according to anotherembodiment of the present general inventive concept. Unlike FIG. 3 inwhich the switching control unit 264 is a PWM IC, in FIG. 5, theswitching control unit 264 is a switching control circuit 564. Otherelements of the SMPS are the same as illustrated in FIG. 3 and thus arenot illustrated in FIG. 5, and a structure between the smoothing circuitunit 540 and a transforming unit 550 is illustrated in FIG. 5.

Referring to FIG. 5, a main switch 562 connected to a primary coil ofthe transforming unit 550 may be a transistor, as illustrated in FIG. 5.A base terminal of the transistor of the main switch 562 and a collectorterminal of a transistor TR2 in the switching control circuit 564 areconnected to each other, and a base terminal of the transistor TR2 inthe switching control circuit 564 is connected to one terminal of aZener diode ZD in an overvoltage detecting unit 580.

A DC voltage output from the smoothing circuit unit 540 including acapacitor C1 is input to the overvoltage detecting unit 580. When a DCvoltage higher than a breakdown voltage of the Zener diode ZD that usesthe breakdown voltage as a reference voltage to determine if theexistence of an overvoltage is input, the DC voltage passes through theZener diode ZD. A signal indicating that an overvoltage is applied istransmitted to the base terminal of the transistor TR2 in the switchingcontrol circuit 564, and the DC voltage passes through the transistorTR2. Accordingly, since a voltage applied to the base terminal of themain switch 562 is grounded by the transistor TR2, the main switch 562no longer performs a switching operation. Accordingly, energy may not betransferred from the primary coil to a secondary side of thetransforming unit 550 and an output voltage is not generated on thesecondary side, thereby preventing an overvoltage from affecting a loadterminal.

FIG. 6 is a block diagram illustrating an SMPS 600 for an image formingapparatus having an overvoltage cutoff function, according to anotherembodiment of the present general inventive concept. Referring to FIG.6, the SMPS 600 includes an AC power input unit 610, a filter unit 620,a rectifying circuit unit 630, a smoothing circuit unit 640, atransforming unit 650, a switching unit 660, an output unit 670, a firstovervoltage detecting unit 680, a cutoff unit 690, and a secondovervoltage detecting unit 695. The switching unit 660 includes a mainswitch 262 and a switching control unit 264. The SMPS 600 of FIG. 6further includes the cutoff unit 690 and the second overvoltagedetecting unit 695, compared to the SMPS 200 of FIG. 2. Since the term‘first’ in the first overvoltage detecting unit 680 of FIG. 6 is used todistinguish the first overvoltage detecting unit 680 from the secondovervoltage detecting unit 695, the first overvoltage detecting unit 680is the same as the overvoltage detecting unit 280 of FIG. 2. A detailedexplanation of the same elements in FIG. 6 as those in FIG. 2 is notprovided.

Referring to FIG. 6, the cutoff unit 690 is disposed between the ACpower input unit 610 and the filter unit 620. The second overvoltagedetecting unit 695 detects an AC voltage output from the AC power inputunit 610, and determines whether the detected AC voltage is anovervoltage by comparing the detected AC voltage with a referencevoltage. The second overvoltage detecting unit 695 outputs a result ofthe determination to the cutoff unit 690. When a signal indicating thatan overvoltage is applied is input from the second overvoltage detectingunit 695 to the cutoff unit 690, the cutoff unit 690 cuts off an ACvoltage output from the AC power input unit 610 to the filter unit 620.As a result, when an AC voltage, which is an overvoltage, is applied tothe SMPS 600, the AC voltage is cut off by the cutoff unit 690, therebypreventing damage to the circuits in the SMPS 600 and the image formingapparatus.

FIG. 7 is a circuit diagram illustrating an SMPS 700 for an imageforming apparatus having an overvoltage cutoff function, according toanother embodiment of the present general inventive concept. Referringto FIG. 7, the SMPS 700 includes an AC power input unit 710, a filterunit 720, a rectifying circuit unit 730, a smoothing circuit unit 740, atransforming unit 750, a main switch 762, a switching control unit 764,an output unit 770, a first overvoltage detecting unit 780, a cutoffunit 790, and a second overvoltage detecting unit 795. It would beunderstood by one of ordinary skill in the art that the SMPS 700 mayfurther include elements other than the elements shown in FIG. 7.

The SMPS 700 of FIG. 7 further includes some elements, compared to theSMPS 300 of FIG. 3, and the description of the SMPS 300 made withreference to FIG. 3 may apply to the SMPS 700 of FIG. 7. The newly addedelements in FIG. 7 will now be explained. Referring to FIG. 7, the SMPS700 is configured such that the cutoff unit 790 and the secondovervoltage detecting unit 795 are disposed between the AC power inputunit 710 and the filter unit 720.

An AC voltage output from the AC power input unit 710 is input to thesecond overvoltage detecting unit 795 that is connected in parallel tothe filter unit 710. The second overvoltage detecting unit 795 mayinclude a second power detecting unit and a second overvoltagedetermining unit according to a detailed function. The second powerdetecting unit of the second overvoltage detecting unit 795 decreases anAC voltage output from the AC power input unit 710 according to atransformation ratio of a potential transformer (PT) to a predeterminedlevel and rectifies the decreased AC voltage by passing the decreased ACvoltage through a diode D. The second overvoltage determining unitincludes a Zener diode ZD reversely connected to the diode D. Abreakdown voltage of the Zener diode ZD may be a reference voltage todetermine the existence of an overvoltage. When the rectified powerinput to the Zener diode ZD is higher than the breakdown voltage, therectified power passes through the Zener diode ZD and a signalindicating that an overvoltage is applied is input to the cutoff unit790. In this case, the signal indicating that an overvoltage is appliedincludes a value obtained by subtracting the preset breakdown voltage ofthe Zener diode ZD from the rectified power.

For example, if the transformation ratio of the PT is 10:1, an ACvoltage output from the AC power input unit 710 is decreased to 1/10 bypassing through the PT. As a result, when an AC voltage is 110 V, powerrectified by the diode D is changed to a DC voltage of about 15.5 V (ifan error of about 15% is allowed and the DC voltage ranges from 1.2 V to17.8 V), and when an AC voltage is 220 V, power rectified by the diode Dis changed to a DC voltage of about 31 V (if an error of about 15% isallowed and the DC voltage ranges from 26.3 V to 35.7 V). In this case,a reference voltage to determine the existence of an overvoltage may beset variously. If the SMPS 700 has a rated voltage of 110 V, when powerrectified by the diode D exceeds 17.8 V, since the power exceeds amaximum allowance of the rated voltage and it may be determined that anovervoltage is applied, a reference voltage may become 17.8 V.Alternatively, whether an AC voltage of 220 V is applied to the SMPS 700that uses 110 V as a rated voltage may be determined. That is, whenpower rectified by the diode D exceeds 26.3 V, the rectified powerexceeds a minimum value of 220 V and it may be determined that anovervoltage of 220 V is applied to the SMPS 700, a reference voltage maybecome 26.3 V.

The cutoff unit 790 may be configured such that a base terminal of atransistor TR is connected between a resistor R1 and a resistor R2, acollector terminal of the transistor TR is connected to one side of arelay RELAY, and an emitter terminal of the transistor TR is grounded. Aswitch SW of the relay RELAY is disposed between the AC power input unit710 and the filter unit 720 and performs a switching operation accordingto the state of an electromagnet in the relay RELAY. Unlike in FIG. 7,the relay RELAY may be a photo triac including a light-emitting diodeand a triac, or a photocoupler including a light-emitting diode and aphototransistor. The cutoff unit 790 operates according to a signaloutput from the second overvoltage detecting unit 795. When powerrectified by the diode D passes through the Zener diode ZD reverselyconnected to the diode D of the second overvoltage detecting unit 795, asignal indicating that an overvoltage is applied is input to the cutoffunit 790, and thus, the transistor TR and the relay RELAY operate. Whenthe relay RELAY is turned on, the electromagnet attracts the switch SW,one side of the switch SW connected to the AC power input unit 710 isseparated from the AC power input unit 710, and an AC voltage outputfrom the AC power input unit 710 to the filter unit 720 is cut off. Onthe contrary, when power rectified by the diode D does not pass throughthe Zener diode ZD reversely connected to the diode D of the secondovervoltage detecting unit 795, there is no signal output to the cutoffunit 790, the transistor TR and the relay RELAY do not operate, theswitch SW connects the AC power input unit 710 and the filter unit 720,and an AC voltage is input to the filter unit 720.

FIG. 8 is a flowchart illustrating a method of cutting off anovervoltage performed by the SMPS 600 of FIG. 6, according to anotherembodiment of the present general inventive concept.

In operation 810, the second overvoltage detecting unit 695 detects anAC voltage output from the AC power input unit 610. The AC voltage isthe same as an AC voltage passing through the cutoff unit 690 and inputto the filter unit 620.

In operation 820, the second overvoltage detecting unit 695 determineswhether the detected AC voltage is an overvoltage by comparing thedetected AC voltage with a second reference voltage. In this case, thesecond overvoltage detecting unit 695 decreases the detected AC voltageto a predetermined level by using the PT, rectifies the decreased ACvoltage, and transforms the rectified AC voltage into a DC voltage. Whenit is determined in operation 820 that the rectified power is lower thanthe second reference voltage, an AC voltage output from the AC powerinput unit 610 is not cut off by the cutoff unit 690 and is input to thefilter unit 620, and passes through the rectifying circuit unit 630 andthe smoothing circuit unit 640, and the method proceeds to operation840. When it is determined in operation 820 that the rectified power ishigher than the second reference voltage, it is determined that anovervoltage is applied and the method proceeds to operation 830.

In operation 830, when a signal indicating that an overvoltage isapplied is input from the second overvoltage detecting unit 695, thecutoff unit 690 cuts off an AC voltage output from the AC power inputunit 610 to the filter unit 620.

In operation 840, the first overvoltage detecting unit 680 detects a DCvoltage passing through the rectifying circuit unit 630 and thesmoothing circuit unit 640 and output from the smoothing circuit unit640. The DC voltage is the same as a DC voltage input to the primarycoil of the transformer of the transforming unit 250.

In operation 850, the first overvoltage detecting unit 680 determineswhether the detected DC voltage is an overvoltage by comparing thedetected DC voltage with a first reference voltage. Since there may be apredetermined time delay for the cutoff unit 690 to cut off an ACvoltage corresponding to an overvoltage, the AC voltage may become a DCvoltage while passing through the rectifying circuit unit 630 and thesmoothing circuit unit 640. Alternatively, the AC voltage may become anabnormal power while passing through the filter unit 620, the rectifyingcircuit unit 630, and the smoothing circuit unit 640. When it isdetermined in operation 850 that the DC voltage detected by the firstovervoltage detecting unit 680 is lower than the first referencevoltage, the SMPS 600 normally operates. Otherwise, when it isdetermined in operation 850 that the detected DC voltage is higher thanthe first reference voltage, an overvoltage has been applied, and themethod proceeds to operation 860.

In operation 860, when a signal indicating that an overvoltage isapplied is input from the first overvoltage detecting unit 680, theswitching control unit 664 stops a switching operation of the mainswitch 662. Accordingly, an output voltage is not generated in theoutput unit 670 connected to the secondary side of the transformer.

In operations 810 through 860, whether an AC voltage applied to the SMPS600 is an overvoltage is determined and the AC voltage is cut off whenit is determined that the AC voltage is an overvoltage. Also, whether aDC voltage input to the primary coil of the transformer is anovervoltage is determined and a switching operation of the main switch662 to adjust an output of the transformer is stopped when it isdetermined that the DC voltage is an overvoltage, thereby preventing anovervoltage from affecting a load terminal connected to the secondaryside of the transformer.

When an AC voltage applied from the outside is an overvoltage higherthan a rated voltage of an SMPS for an image forming apparatus, damageto circuits in the SMPS and the image forming apparatus may beprevented.

While the present invention has been particularly shown and describedwith reference to exemplary embodiments thereof using specific terms,the embodiments and terms have been used to explain the present generalinventive concept and should not be construed as limiting the scope ofthe present general inventive concept defined by the claims. Theexemplary embodiments should be considered in a descriptive sense onlyand not for purposes of limitation. Therefore, the scope of the presentgeneral inventive concept is defined not by the detailed description ofthe present general inventive concept but by the appended claims, andall differences within the scope will be construed as being included inthe present general inventive concept.

What is claimed is:
 1. A switching-mode power supply (SMPS) for an imageforming apparatus, the SMPS comprising: a rectifying circuit unit torectify an alternating-current (AC) voltage input from an external powersupply source into a direct-current (DC) voltage; a transformer totransform the rectified DC voltage input to a primary coil and to outputthe transformed DC voltage to a secondary coil; a main switch that isconnected to the primary coil to switch an output of the transformer; afirst overvoltage detecting unit to determine whether the rectified DCvoltage is an overvoltage by comparing the rectified DC voltage with afirst reference voltage; and a switching control unit to control aswitching operation of the main switch based on a result of thedetermination.
 2. The SMPS of claim 1, wherein the switching controlunit stops the switching operation when it is determined that therectified DC voltage is an overvoltage.
 3. The SMPS of claim 2, whereinthe switching control unit is a pulse width modulation (PWM) integratedcircuit (IC) and stops the switching operation when a signal indicatingan overvoltage is input to a predetermined pin of the PWM IC from thefirst overvoltage detecting unit.
 4. The SMPS of claim 1, wherein thefirst overvoltage detecting unit comprises: a power detecting unit todetect the rectified DC voltage; and a first overvoltage determiningunit to determine whether the detected DC voltage is an overvoltage bycomparing the detected DC voltage with the first reference voltage. 5.The SMPS of claim 4, wherein the first overvoltage determining unitdetermines whether the detected DC voltage is an overvoltage with aZener diode that has the first reference voltage as a breakdown voltage.6. The SMPS of claim 1, wherein the first overvoltage detecting unitdetermines whether the rectified DC voltage is an overvoltage bydetermining whether the rectified DC voltage is higher than the firstreference voltage that corresponds to a maximum allowance of a ratedvoltage of the SMPS.
 7. The SMPS of claim 1, further comprising: asecond overvoltage detecting unit to transform the input AC voltage andto determine whether the transformed AC voltage is an overvoltage bycomparing the transformed AC voltage with a second reference voltage;and a cutoff unit to cut off the input AC voltage input to therectifying circuit based on a result of the determination of the secondovervoltage detecting unit.
 8. The SMSP device of claim 7, wherein thesecond overvoltage detecting unit comprises: a potential transformer totransform the input AC voltage according to a predetermined turns ratio;a rectifier to rectify the transformed AC voltage into a DC voltage; anda second overvoltage determining unit to determine whether the DCvoltage rectified by the rectifier is an overvoltage by comparing therectified DC voltage with the second reference voltage.
 9. The SMPS ofclaim 8, wherein the second overvoltage determining unit determineswhether the rectified DC voltage is an overvoltage by using a Zenerdiode that has the second reference voltage as a breakdown voltage. 10.The SMPS of claim 7, wherein the cutoff unit cuts off the input ACvoltage input to the rectifying circuit unit by using any one of arelay, a photo triac, and a photocoupler.
 11. A method of cutting off anovervoltage performed by a switching-mode power supply (SMPS) for animage forming apparatus, the method comprising: detecting adirect-current (DC) voltage obtained by rectifying analternating-current (AC) voltage input from an external power supplysource; determining whether the detected DC voltage is an overvoltage bycomparing the detected DC voltage with a first reference voltage; andcontrolling a switching operation of a main switch that switches anoutput of a transformer for transforming the rectified DC voltage, basedon a result of the determination.
 12. The method of claim 11, whereinthe controlling comprises: stopping the switching operation when it isdetermined that the detected DC voltage is an overvoltage.
 13. Themethod of claim 11, wherein the determining whether the detected DCvoltage is an overvoltage comprises: determining whether the detected DCvoltage is an overvoltage by determining whether the detected DC voltageis higher than the first reference voltage that corresponds to a maximumallowance of a rated voltage of the SMPS.
 14. The method of claim 11,further comprising: transforming the input AC voltage and determiningwhether the transformed AC voltage is an overvoltage by comparing thetransformed AC voltage with a second reference voltage; and cutting offthe input AC voltage before the input AC voltage is rectified, based ona result of the determination.
 15. The method of claim 14, wherein thedetermining whether the transformed AC voltage is an overvoltage bycomparing the transformed AC voltage with the second reference voltagecomprises: transforming the input AC voltage according to apredetermined turns ratio by using a potential transformer; rectifyingthe transformed AC voltage into a DC voltage; and determining whetherthe rectified DC voltage is an overvoltage by comparing the rectified DCvoltage with the second reference voltage.
 16. An image formingapparatus comprising a switching-mode power supply (SMPS), wherein theSMPS comprises: a rectifying circuit unit to rectify analternating-current (AC) voltage input from an external power supplysource into a direct-current (DC) voltage; a transformer to transformthe rectified DC voltage input to a primary coil and to output thetransformed DC voltage to a secondary coil; a main switch that isconnected to the primary coil to switch an output of the transformer; afirst overvoltage detecting unit to determine whether the rectified DCvoltage is an overvoltage by comparing the rectified DC voltage with afirst reference voltage; and a switching control unit to control aswitching operation of the main switch based on a result of thedetermination.
 17. The image forming apparatus of claim 16, wherein theSMPS further comprises: a second overvoltage detecting unit to transformthe input AC voltage and determines whether the transformed AC voltageis an overvoltage by comparing the transformed AC voltage with a secondreference voltage; and a cutoff unit to cut off the input AC voltageinput to the rectifying circuit based on a result of the determinationof the second overvoltage detecting unit.
 18. A switching-mode powersupply (SMPS) comprising: a rectifying unit to rectify a voltage inputfrom a supply source; a first overvoltage detecting unit to detect thevoltage rectified by the rectifying unit and to determine if the voltageis within a predetermined voltage range; and a switching control unit tostop a switching operation of a main switch that is connected to theswitching control unit to prevent an output unit from outputting thevoltage when the detected voltage is greater than the predeterminedvoltage range.
 19. The switching-mode power supply of claim 18, whereinthe switching control unit controls the switching operation of the mainswitch to prevent the output unit from generating an output voltagegreater than the predetermined voltage range.
 20. The switching-modepower supply of claim 18, wherein the first overvoltage detecting unitcomprises: an overvoltage determining unit to allow the firstovervoltage detecting unit to determine if the voltage input from thesupply source is greater than the predetermined voltage range.
 21. Theswitching-mode power supply of claim 18, wherein the first overvoltagedetecting unit comprises: a Zener diode to allow the first overvoltagedetecting unit to determine if the voltage input from the supply sourceis greater than the predetermined voltage range.
 22. The switching-modepower supply of claim 18, further comprising: a second overvoltagedetecting unit to detect the voltage input from the supply source and todetermine if the voltage is greater than the predetermined voltagerange; and a cutoff unit to prevent the voltage input from the supplysource from entering a filter unit when the voltage is greater than thepredetermined voltage range.
 23. The switching-mode power supply ofclaim 22, wherein the second overvoltage detecting unit comprises: aZener diode to allow the second overvoltage detecting unit to determineif the voltage input from the supply source is greater than thepredetermined voltage range.